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For $G$ a group and

H \xhookrightarrow{\iota} G

a subgroup, write

(1)

\iota^\ast \;\colon\; G Rep_{\mathbb{C}} \xrightarrow{\;} H Rep_{\mathbb{C}}

for the functor of restricted representations.

Proposition 0.1. The functor $\iota^\ast$ (1) has a right adjoint $\iota_\ast \colon H Rep_{\mathbb{C}} \xrightarrow{\;} G Rep_{\mathbb{C}}$ given by

V \in H Rep_{\mathbb{C}} \;\;\;\;\;\; \vdash \;\;\;\;\;\; \iota_{\ast} V \;\coloneqq\; Hom_H\big( \mathbb{C}[H] ,\, V \big) \,,

where on the right we have the vector space of $H$ -equivariant linear maps equipped with the $G$ -group action given by

\left. \begin{array}{l} f \,\colon\, \mathbb{C}[H] \xrightarrow{\;} V \\ g \,\in\, G \end{array} \right\} \;\;\;\;\;\; \vdash \;\;\;\;\;\; g \cdot f \,\coloneqq\, f(- \cdot g) \,.

Proof. We claim that the hom-isomorphism is given by evaluation at the neutral element $\mathrm{e} \in G$ :

\left. \begin{array}{l} V \,\in\, H Rep \\ W \,\in\, G Rep \end{array} \right\} \;\;\;\;\;\;\;\; \vdash \;\;\;\;\;\;\;\; \frac{ W \xrightarrow{\;\;\;\; f \;\;\;\;} \overset{\iota_\ast V}{ \overbrace{ Hom_{H}\big( \mathbb{C}[H] ,\, V \big) } } }{ \iota^\ast W \xrightarrow{\;\; f(-)(\mathrm{e}) \;\;} V }

To see this, just observe that

\left. \begin{array}{l} f \,\in\, Hom_G\Big( W ,\, Hom_H\big( \mathbb{C}[H] ,\, V \big) \Big) \\ h \,\in\, H \end{array} \right\} \;\;\;\;\;\;\; \vdash \;\;\;\;\;\;\; f(h \cdot -)(\mathrm{e}) \;=\; \big( h \cdot f(-)\big)(\mathrm{e}) \;=\; f(-)(\mathrm{e} \cdot h) \;=\; f(-)(h) \,,

where the first equality is the $G$ -equivariance of $f$ , and the second is the $H$ -equivariance of $f(-)$ . This shows that $f(-)(\mathrm{e})$ is $H$ -equivariant and that it uniquely determines $f$ .

▮

On electrodynamics via field strengths instead of gauge potentials:

Joshua Newey, John Terning, Christopher B. Verhaaren: Geometrizing the Anomaly [arXiv:2504.16998]

Last revised on April 29, 2025 at 18:07:36. See the history of this page for a list of all contributions to it.